The present patent application claims the priority of Japanese patent application No. 2019/188516 filed on Oct. 15, 2019, and the entire contents of Japanese patent application No. 2019/188516 are hereby incorporated by reference.
The present invention relates to an operation device.
A power window switch to open and close vehicle windows is known (see, e.g., Patent Literature 1).
This power window switch has plural switch buttons attached to a switch box via support shafts so that front ends can be operated and pivoted up and down. The switch button has switch portions at the front end and the rear end and is configured such that the switch portion on the front-end side is turned on when the front end is operated and pivoted in a downward direction, and the switch portion on the rear end side is turned on when the front end is operated and pivoted in an upward direction.
When, e.g., the power window switch disclosed in Patent Literature 1 is configured to be capable of instructing to open and close front and rear seat windows by one switch button instead of by the plural switch buttons and is also configured to detect contact with regions set on the front seat side and the rear seat side, and if the user tries to operate the front seat side region of the switch button and touches also the rear seat side region, an erroneous determination to cause unintended windows to be opened or closed may occur.
It is an object of the invention to provide an operation device that can suppress erroneous determination against intention of a user.
An operation device in an embodiment of the invention comprises:
According to an embodiment of the invention, an operation device can be provided that can suppress erroneous determination against intention of a user.
An operation device in an embodiment has an operation knob that is operable by a pull-up operation and a push-down operation about a shaft and has a front-end operation region on a front end side far from the shaft and a rear-end operation region on a rear end side closer to the shaft, a contact detection unit to detect contact of a user with the front-end operation region and the rear-end operation region, an operation detection unit to detect the pull-up operation and the push-down operation performed on the operation knob, and a determination unit that determines an operation performed by combining contact with the front-end operation region and the rear-end operation region detected by the contact detection unit and the pull-up operation and the push-down operation detected by the operation detection unit, and also determines that at least an operation performed on the rear-end operation region is invalid when contact with the front-end operation region and the rear-end operation region is detected.
The operation device assumes that a user could accidentally touch the rear-end operation region 23 at the time of operating the front-end operation region, and it is configured such that when contact with the front-end operation region and the rear-end operation region is detected, at least an operation performed on the rear-end operation region is determined to be invalid. Therefore, it is possible to suppress erroneous determination against intention of a user, as compared to when the operations on both regions are determined to be valid.
(General Configuration of an Operation Device 1)
As shown in
As an example, the operation device 1 in the present embodiment is arranged in a four-door vehicle 8, as shown in
(Configuration of the Operation Knob 2)
The operation knob 2 is arranged in a recessed portion 12 of a main body 10, as shown in
The operation knob 2 is formed of a resin material. The operation knob 2 has a groove 24 on a surface 20, and the surface 20 is divided at the groove 24 into the front-end operation region 21 on a front-end side far from the shaft 26 and the rear-end operation region 23 on a rear end side close to the shaft 26.
As shown in
As shown in
Furthermore, the operation knob 2 has such a shape that the vertex 20b is located higher than the vertex 20a, as shown in
The front-end operation region 21 is a region to operate the window 81a of the right front door 81 and the window 82a of the left front door 82. The rear-end operation region 23 is a region to operate the window 83a of the right rear door 83 and the window 84a of the left rear door 84.
Furthermore, the front-end operation region 21 has a first operation region 21a and a second operation region 21b to instruct to open and close the right front window 81a and the left front window 82a of the vehicle 8. Likewise, the rear-end operation region 23 has a third operation region 23a and a fourth operation region 23b to instruct to open and close the right rear window 83a and the left rear window 84a of the vehicle 8.
The first operation region 21a is a region on the upper side of a dotted line drawn at the center of the front-end operation region 21 in
The third operation region 23a is a region on the upper side of a dotted line drawn at the center of the rear-end operation region 23 in
Since the operation knob 2 has the first to fourth operation regions 21a to 23b as described above, the four windows 81a to 84a can be operated by one knob and the size is small.
(Configuration of the Contact Detection Unit 3)
The contact detection unit 3 in the present embodiment is a capacitive touch sensor that detects proximity or contact of a detection target to/with the first to fourth operation regions 21a to 23b of the operation knob 2.
In particular, as shown in
The right front detection electrode 31 to the left rear detection electrode 34 are formed of a conductive metal material. The right front detection electrode 31 to the left rear detection electrode 34 are arranged on the operation knob 2 at a boundary between the surface 20 and the side surface 22 and a boundary between the surface 20 and the groove 24, i.e., at the corners on both sides of the vertex 20a and the vertex 20b. In addition, the right front detection electrode 31 to the left rear detection electrode 34 are exposed on the surface 20, the side surface 22 and the groove 24 to detect contact with the surface 20 as well as contact with the side surface 22 and the groove 24.
The right front detection electrode 31 to the left rear detection electrode 34 have a long shape as shown in
The sensor control unit 35 is a microcomputer composed of a CPU (=Central Processing Unit) performing calculation and processing, etc., of the acquired data according to a stored program, and a RAM (=Random Access Memory) and a ROM (=Read Only Memory) as semiconductor memories, etc. The ROM stores a program for operation of the sensor control unit 35. The RAM is used as a storage area to temporarily store calculation results, etc. The sensor control unit 35 also has, inside thereof, a means to generate a clock signal and operates based on the clock signal. This clock signal is synchronized with the control unit 6.
The sensor control unit 35 is, e.g., an electrostatic sensor IC (=Integrated Circuit). The contact detection unit 3 is configured as a self-capacitance type touch sensor in which capacitance increases when the operation finger of the user comes in proximity or contact with the right front detection electrode 31 to the left rear detection electrode 34. The sensor control unit 35 has an electrostatic threshold value 350 in the RAM or the ROM and determines that there is proximity or contact of the operation finger of the user when capacitance of not less than the electrostatic threshold value 350 is detected. In this regard, the contact detection unit 3 is not limited to the self-capacitance type touch sensor and may be a mutual-capacitance type touch sensor or another type of touch sensor.
The first to fourth output signals S1 to S4 acquired by the sensor control unit 35 from the right front detection electrode 31 to the left rear detection electrode 34 are analog signals. The sensor control unit 35 determines whether or not there is proximity or contact for each of the right front detection electrode 31 to the left rear detection electrode 34, and outputs the result as a detection signal S5 to the electrically connected control unit 6. The detection signal S5 is a digital signal. The sensor control unit 35 is connected to the control unit 6 by a flexible cable.
The sensor control unit 35 is mounted on the sub-substrate 30 (shown in
Since the contact detection unit 3 is arranged on the operation knob 2 and sends the detection result to the main body 10 side using digital signals instead of analog signals, it is less likely to be affected by external noise as compared to when sending analog signals. As a result, the operation device 1 has high accuracy in detecting the operation finger of the user.
The contact detection unit 3 is not limited to the touch sensor and may be a pressure sensor, etc., that detects contact with the operation knob 2, as a modification.
Here, the sensor control unit 35 takes a time of at least about 30 ms to detect the operation finger, as an example. This time involves A/D conversion of electrode voltage, a correction process for the detection electrodes to improve accuracy of capacitance detection, measurement of a reference value of capacitance, a process to calculate a difference value between the reference value of capacitance and a current capacitance value and confirm the capacitance value, and time for data transmission, etc.
Thus, at the time of determining a control pattern (described later), the control unit 6 does not determine it at the time the switch is turned “ON”, but determines it with a delay after the switch is turned “ON”, by taking into consideration the delay in the processing of the contact detection unit 3. This delay is not less than time required to confirm detection, as an example. In consideration of this delay, the time at which determination is made will be described as the time at which “ON” of the switch is confirmed, etc., in the following description.
(Configuration of the Operation Detection Unit 4)
As shown in
Each of the switch 43 and the switch 44 is composed of two switches, as an example. As shown in
When the operation knob 2 is pulled up, a first switch of the switch 43 is firstly turned into the ON state (the first ON state). When the operation knob 2 is further pulled up, the first switch and a second switch of the switch 43 are turned into the ON state (the second ON state). Likewise, when the operation knob 2 is pushed down, a first switch of the switch 44 is firstly turned into the ON state (the first ON state). When the operation knob 2 is further pushed down, the first switch and a second switch of the switch 44 are turned into the ON state (the second ON state).
A mode when the operation knob 2 is pulled up and the switch 43 is turned to the first ON state is a manual mode in which the window is driven in a closing direction. A mode when the operation knob 2 is further pulled up and the switch 43 is turned to the second ON state is an automatic mode in which the window is driven until fully closed.
A mode when the operation knob 2 is pushed down and the switch 44 is turned to the first ON state is the manual mode in which the window is driven in an opening direction. A mode when the operation knob 2 is further pushed down and the switch 44 is turned to the second ON state is the automatic mode in which the window is driven until fully opened.
The operation detection unit 4, when detected pulling-up of the operation knob 2, outputs a switch signal S6 corresponding to the ON state from the switch 43 to the electrically connected control unit 6. Meanwhile, the operation detection unit 4, when detected pushing-down of the operation knob 2, outputs a switch signal S7 corresponding to the ON state from the switch 44 to the electrically connected control unit 6.
(Configuration of a Storage Unit 5)
A storage unit 5 is electrically connected to the control unit 6. The storage unit 5 may be an external storage device connected outside the control unit 6, or may be a RAM of the control unit 6 or a semiconductor memory provided on a main substrate 13.
The storage unit 5 stores control pattern information 50 to determine a driving direction and a window to be driven, by a combination of an operation region in which an operation is detected by the contact detection unit 3 and a pull-up operation and a push-down operation detected by the operation detection unit 4.
The control pattern information 50 is information of control patterns in which “ON” and “OFF” timings of the right front detection electrode 31 to the left rear detection electrode 34 and the switches 43, 44, an operation signal S8 to be output, and validity or invalidity of the operation are combined. Control patterns, which are based on the control pattern information 50 and are about the “ON” and “OFF” timings of the detection electrodes and the switches, the operation signal output at such timings, and validity or invalidity of the operation, will be described in
(Configuration of the Control Unit 6)
The control unit 6 is a microcomputer composed of a CPU performing calculation and processing, etc., of the acquired data according to a stored program, and a RAM and a ROM as semiconductor memories, etc. The ROM stores a program for operation of the control unit 6. The RAM is used as a storage area to temporarily store calculation results, etc. The control unit 6 also has, inside thereof, a means to generate a clock signal and operates based on the clock signal.
The control unit 6 generates the operation signal S8 based on the determined control pattern, and outputs it to the window driving device 85 that drives windows in an opening direction and a closing direction. In consideration of the delay of confirmation of detection of the operation finger, the control unit 6 determines the control pattern at the time “ON” of the switch is confirmed, as described above. In this regard, the window driving device 85 is configured to stop driving without instruction from the operation device 1 once the window is fully opened and fully closed.
Next, control patterns based on the “ON” and “OFF” timings will be described with reference to the drawings in
The horizontal axis in
“ON” and “OFF” of the right front detection electrode 31 to the left rear detection electrode 34 indicate detection and no detection of the operation finger. “ON” and “OFF” of the (pull-up side) switch 43 and the (push-down side) switch 44 indicate detection and no detection of a pull-up operation and a push-down operation. The manual mode will be described here, but the same applies to the automatic mode. In addition, “ON” and “OFF” of the operation signal S8 indicate an instruction to drive and no instruction.
(Control Patterns)
First Control Pattern
In
That is, when there is a detection electrode that is “ON” at the time “ON” of the switch 43 or the switch 44 is confirmed, the control unit 6 outputs the operation signal S8 to drive a window corresponding to this detection electrode.
Once acquiring the detection signal S5 indicating that the right front detection electrode 31 is turned “ON” and the switch signal S6 indicating that the pull-up side switch 43 is turned “ON”, the control unit 6 determines, based on the control pattern information 50, that the operation to close the window 81a is valid.
The control unit 6 starts outputting the operation signal S8a to close the window 81a at the time t2. Then, since the switch 43 is turned “OFF” before the right front detection electrode 31 is turned “OFF”, the control unit 6 stops outputting the operation signal S8a at the time t3 at which the switch 43 is turned “OFF”.
In the case of the first control pattern in the manual mode, the control unit 6 keeps outputting the operation signal S8 while the switch is “ON”. Meanwhile, in the automatic mode, the control unit 6 outputs the operation signal S8 to instruct to fully open or fully close, based on time at which the automatic mode is determined.
Second Control Pattern
In
That is, when plural detection electrodes of the front-end operation region 21 or the rear-end operation region 23 are “ON” at the time “ON” of the switch 43 or the switch 44 is confirmed, the control unit 6 outputs the operation signal S8 to drive windows corresponding to these plural detection electrodes. The control unit 6 also stops driving the window corresponding to the detection electrode which no longer detects the operation finger, among the plural detection electrodes which are detecting the operation finger.
Once acquiring the detection signal S5 indicating that the right front detection electrode 31 and the left front detection electrode 32 are turned “ON” and the switch signal S7 indicating that the push-down side switch 44 is turned “ON”, the control unit 6 determines, based on the control pattern information 50, that the operation to open the window 81a and the window 82a is valid, since the switch is turned “ON” after the operation finger is detected.
The control unit 6 starts outputting the operation signal S8a and the operation signal S8b to open the window 81a and the window 82a at the time t12. Then, since the left front detection electrode 32 is turned “OFF” at the time t13 before the switch 44 is turned “OFF”, the control unit 6 stops outputting the operation signal S8b. After that, since the switch 44 is turned “OFF” first at the time t14, the control unit 6 stops outputting the operation signal S8a at the time t14 at which the switch 44 is turned “OFF”.
In the case of the second control pattern in the manual mode, the control unit 6 keeps outputting the operation signal S8 to drive the windows corresponding to the detection electrodes of the front-end operation region 21 or the rear-end operation region 23 which detected the operation finger, during when the switch is “ON”. Meanwhile, in the automatic mode, the control unit 6 outputs the operation signal S8 to instruct to fully open or fully close the plural windows corresponding to the detection electrodes of the front-end operation region 21 or the rear-end operation region 23 which detected the operation finger, based on time at which the automatic mode is determined.
Third Control Pattern
In
That is, when “ON” of the switch is confirmed and after that the detection electrode is turned “OFF” before the switch is turned “OFF”, the control unit 6 stops driving the window corresponding to this detection electrode.
Once acquiring the detection signal S5 indicating that the right rear detection electrode 33 is turned “ON” and the switch signal S6 indicating that the pull-up side switch 43 is turned “ON”, the control unit 6 determines, based on the control pattern information 50, that the operation to close the rear window 83a on the driver's seat side is valid, since the switch is turned “ON” after the operation finger is detected.
The control unit 6 starts outputting the operation signal S8c to close the window 83a at the time t21. Then, since the right rear detection electrode 33 is turned “OFF” before the switch 43 is turned “OFF”, the control unit 6 stops outputting the operation signal S8c at the time t22 at which detection becomes “OFF”.
In the case of the third control pattern in the manual mode, the control unit 6 stops outputting the operation signal S8 since the detection of the operation finger becomes “OFF” before the switch is turned “OFF”. Meanwhile, in the automatic mode, the control unit 6 stops an output indicating that detection is “OFF”, before outputting the operation signal S8 to instruct to fully open or fully close based on time at which the automatic mode is determined.
Fourth Control Pattern
In
When the switch is turned “ON” before the operation finger is detected, the control unit 6 does not drive the window corresponding to the relevant detection electrode.
When the detection electrode is “OFF” at the time “ON” of the pull-up side switch 43 is confirmed, the control unit 6 determines to not drive the window based on the control pattern information 50.
Fifth Control Pattern
When contact with the front-end operation region 21 and the rear-end operation region 23 is detected, the control unit 6 determines that a pull-up operation and a push-down operation performed on the front-end operation region 21 are valid.
In
When the user operates the first operation region 21a using a fingertip 90 of the operation finger 9 as shown in
Thus, when contact with the front-end operation region 21 and the rear-end operation region 23 is detected, the control unit 6 determines that the operation performed on the front-end operation region 21 is valid. In
In the case of the fifth control pattern in the manual mode, the control unit 6 invalidates the operation performed on the rear-end operation region 23, and outputs the operation signal S8 to drive the window corresponding to the detection electrode of the front-end operation region 21 that is detecting the operating finger during when the switch is “ON”.
Meanwhile, in the automatic mode, based on time at which the automatic mode is determined, the control unit 6 invalidates the operation performed on the rear-end operation region 23 and outputs the operation signal S8 to instruct to fully open or fully close the window corresponding to the detection electrode of the front-end operation region 21 which detected the operating finger.
As a modification, when contact with the front-end operation region 21 and the rear-end operation region 23 is detected, the control unit 6 determines that the operations performed on the front-end operation region 21 and the rear-end operation region 23 are invalid.
In this modification, even when the detection electrodes of the front-end operation region 21 and the rear-end operation region 23 are turned “ON”, the control unit 6 does not output the operation signal S8a as indicated by a dotted line in
Sixth Control Pattern
In
When contact with the front-end operation region 21 and the rear-end operation region 23 has been detected at the time “ON” of the switch is confirmed, the control unit 6 determines that the operation performed on the front-end operation region 21 is valid. In
In
In the case of the sixth control pattern in the manual mode, the control unit 6 invalidates the operation performed on the rear-end operation region 23, and outputs the operation signal S8 to drive the window corresponding to the detection electrode of the front-end operation region 21 which is detecting the operating finger during when the switch is “ON” or during when the detection electrode of the front-end operation region 21 is “ON”. Meanwhile, in the automatic mode, based on time at which the automatic mode is determined, the control unit 6 invalidates the operation performed on the rear-end operation region 23 and outputs the operation signal S8 to instruct to fully open or fully close the window corresponding to the detection electrode of the front-end operation region 21 which detected the operating finger.
Seventh Control Pattern
In
Based on the control pattern information 50, the control unit 6 invalidates the invalidates the detection of the operation finger by the right rear detection electrode 33 which is turned “ON” during driving. Then, the control unit 6 outputs the operation signal S8d until the left rear detection electrode 34 is turned “OFF” or the switch 43 is turned “OFF”.
In the case of the seventh control pattern in the manual mode, the control unit 6 invalidates the detection of the operation finger by the other detection electrode during driving, and outputs the operation signal S8 to drive the window until the switch is turned “OFF” or until the detection electrode which detected the operation finger first is turned “OFF”. Meanwhile, in the automatic mode, once the automatic mode is determined, the control unit 6 outputs the operation signal S8 to instruct to fully open or fully close the window corresponding to the detection electrode which detected the operating finger.
Eighth Control Pattern
In
In
During driving, even if the right front detection electrode 31 is turned “ON”, the control unit 6 invalidates this operation based on the control pattern information 50. Then, the control unit 6 outputs the operation signal S8c until the right rear detection electrode 33 is turned “OFF” or the switch 43 is turned “OFF”.
In the case of the eighth control pattern in the manual mode, the control unit 6 invalidates the detection of the operation finger by the detection electrode during driving, and outputs the operation signal S8 to drive the window until the switch is turned “OFF” or until the detection electrode which detected the operation finger first is turned “OFF”. Meanwhile, in the automatic mode, once the automatic mode is determined, the control unit 6 outputs the operation signal S8 to instruct to fully open or fully close the window corresponding to the detection electrode which detected the operating finger.
An example of an operation of the operation device 1 in the present embodiment will be described with reference to the flowchart of
(Operation)
The control unit 6 of the operation device 1 acquires the detection signal S5 from the contact detection unit 3 and the switch signal S6 and the switch signal S7 from the operation detection unit 4. When it is “Yes” in Step 1, i.e., when “ON” of the switch is confirmed (Step 1: Yes), the control unit 6 checks if any detection electrode is “ON” at the time the confirmation is made.
When the detection electrode is “ON” at the time the confirmation is made (Step 2: Yes) and when there is only one detection electrode which is “ON” (Step 3: Yes), the control unit 6 drives the window corresponding to the detection electrode which detected the operation finger (Step 4), based on the control pattern information 50. This driving of the window is performed by outputting the operation signal S8 to the window driving device 85 and is stopped when the driven window is fully opened or fully closed, or when the detection electrode is turned from “ON” to “OFF” or the switch is turned from “ON” to “OFF”.
Meanwhile, when, in Step 2, the detection electrodes are “OFF” at the time “ON” of the switch is confirmed (Step 2: No), the control unit 6 determines that this operation is invalid based on the control pattern information 50, and ends the operation (Step 5).
Meanwhile, when there are plural detection electrodes which detected the operation finger in Step 3 (Step 3: No) and also when these detection electrodes are located only on the front seat side (in the front-end operation region 21) or only on the rear seat side (in the rear-end operation region 23) (Step 6: Yes), the control unit 6 drives plural windows corresponding to the plural detection electrodes which detected the operation finger (Step 7), based on the control pattern information 50.
Meanwhile, when the detection electrodes which detected the operation finger are located both on the front seat side (in the front-end operation region 21) and on the rear seat side (in the rear-end operation region 23) in Step 6 (Step 6: No), the control unit 6 invalidates the rear seat side (the rear-end operation region 23) and preferentially drives the window on the front seat side (the front-end operation region 21). As a modification, when the detection electrodes which detected the operation finger are located both on the front seat side (in the front-end operation region 21) and on the rear seat side (in the rear-end operation region 23) (Step 6: No), the control unit 6 invalidates both the front seat side (the front-end operation region 21) and the rear seat side (the rear-end operation region 23).
The operation device 1 in the present embodiment can suppress erroneous determination against intention of the user. For example, when the user performs a pull-up operation or a push-down operation on the front-end operation region 21, the operation may be determined by proximity or contact of the pulp portion 91 of the operation finger 9 to/with the rear-end operation region 23, resulting in driving an unintended window which corresponds to the rear-end operation region 23. The operation device 1 assumes such erroneous determination and prioritizes the front-end operation region 21 when the detection electrodes of the front-end operation region 21 and the rear-end operation region 23 are “ON” at the time “ON” of the switch is confirmed. Therefore, it is possible to suppress erroneous determination against intention of the user, as compared to when such a configuration is not adopted.
The operation device 1 can instruct to open and close the windows 81a-84a by one operation knob 2 and is thus small in size as compared to when four operation knobs are provided. Since the operation knob 2 is small in size, the operation device 1 may detect contact with the rear-end operation region 23 which is not intended by the user. However, when the operation finger is detected in the front-end operation region 21 and the rear-end operation region 23, the operation performed on the front-end operation region 21 is determined to be valid and the operation performed on the rear-end operation region 23 is determined to be invalid. Therefore, the operation device 1 can suppress erroneous determination against intention of the user as compared to when such a configuration is not adopted.
The operation device 1 makes determination while taking into consideration the delay in the processing of the contact detection unit 3 and thus can make determination with high accuracy as compared to when determination is made at the time the switch is turned “ON”.
Although some embodiment and modifications of the invention have been described, these embodiment and modifications are merely an example and the invention according to claims is not to be limited thereto. These new embodiment and modifications thereof may be implemented in various other forms, and various omissions, substitutions and changes, etc., can be made without departing from the gist of the invention. In addition, not all combinations of the features described in these embodiment and modifications are necessary to solve the problem of the invention. Further, these embodiment and modifications thereof are included within the scope and gist of the invention and also within the invention described in the claims and the range of equivalency.
Number | Date | Country | Kind |
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2019-188516 | Oct 2019 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2020/036466 | 9/25/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2021/075238 | 4/22/2021 | WO | A |
Number | Name | Date | Kind |
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10790100 | R | Sep 2020 | B1 |
20200280314 | Adachi | Sep 2020 | A1 |
20210143818 | Carvalho | May 2021 | A1 |
20210194483 | Cannon | Jun 2021 | A1 |
20210247945 | Goto | Aug 2021 | A1 |
20220154517 | Ito | May 2022 | A1 |
Number | Date | Country |
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2005-108621 | Apr 2005 | JP |
Number | Date | Country | |
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20230063651 A1 | Mar 2023 | US |